Patterning processes in aggregates of Hydra cells visualized with the monoclonal antibody, TS19

The monoclonal antibody, TS19, (Heimfeld et al., 1985), labels the apical surface of ectodermal epithelial cells of tentacles and lower peduncles in Hydra. To investigate the patterning process in a tissue whose original pattern was completely destroyed, the TS19 staining pattern was examined in developing aggregates of Hydra cells. Two types of aggregates were prepared. G-aggregates were made from tissue of the gastric portion of animals and RG-aggregates from gastric tissue allowed to regenerate for 24 hr before making aggregates. G-aggregates were initially TS19-negative, and later dim and uniformly TS19-positive. Thereafter, TS19 staining broke up into brightly stained and unstained regions. The brightly staining regions developed into head or foot structures. The TS19 pattern in RG-aggregates developed differently. Since the initial aggregates contained cells of regenerating tips, they started with TS19-positive cells as well as TS19-negative cells. The numbers of brightly staining TS19-positive cells increased with time. Some patches of these cells developed into head or foot structures, while others did not. These results and a simulation using a reaction-diffusion model suggest that the changes in activation levels affected the temporal changes in the pattern of TS19 staining, and that the de novo pattern formation in hydra can be explained in terms of a process involving activation and inhibition properties.     

Patterning of the head in hydra as visualized by a monoclonal antibody: III. The dynamics of head regeneration

The dynamics of the early patterning processes leading to the regeneration of a head in tissue excised from the body column of Hydra oligactis were examined by using a monoclonal antibody, CP8. This antibody displays position-specific binding, labeling the head ectodermal epithelial cells. During regeneration of a head, antibody labeling is present well before morphological signs of the head, at a time correlated with the determination of the tissue (Javois et al., Dev. Biol., 117:607-618, '86). By quantifying antibody labeling during regeneration of three different pieces of tissue excised from the body column, it was found that the dynamics of the early patterning processes as visualized by CP8 labeling varied. The pattern of labeling observed as well as the spread of labeled tissue suggested that the amount and geometry of apical tissue in the regenerate played a critical role in the patterning processes. Contrary to the labeling pattern observed in heads which formed during bud development or which regenerated following decapitation (Javois et al., '86), not all the CP8+ tissue was confined to the head structures in these regenerates. Several alternative explanations for this surprising result are presented. The usefulness of these data in refining pattern formation models by more explicitly constraining their parameters is discussed.     

Patterning of the head in hydra as visualized by a monoclonal antibody. I. Budding and regeneration

A monoclonal antibody, CP8, has been isolated which displays a position-specific binding pattern to epithelial cells of Hydra oligactis. Antibody binding is restricted to the head of adult animals. When a new head develops during the budding process, CP8 binding is present in the area which will form the head well before morphological signs of it. Similarly, following decapitation as a new head regenerates, CP8 label appears covering a domed area at the apical end of the regenerate before tentacles evaginate delineating the head. When bud development or regeneration is complete, CP8 label is restricted to the new head. Experiments indicate the appearance of CP8 label during the formation of a head correlates closely with the patterning events which result in the determination of the tissue to form a head. The usefulness of CP8 as a diagnostic tool for exploring the dynamics of head pattern formation in hydra is discussed.     

In the multiheaded strain (mh-1) of Hydra magnipapillata the ectodermal epithelial cells are responsible for the formation of additional heads and the endodermal epithelial cells for the reduced ability to regenerate a foot

Hydra consist of three self-renewing cell lineages: the ectodermal epithelial, endodermal epithelial and interstitial cell lineages. The role of these cell lineages in head formation and foot regeneration in Hydra magnipapillata was studied by comparing the multiheaded strain mh-1 with the wild-type. Adult polyps of this strain show a reduced ability to regenerate a foot in the apical body half several days before additional heads are formed there. Cell lineage chimeras were produced, and it was found that in mh-1, the ectodermal epithelial cell lineage is responsible for the formation of additional heads, whereas the endodermal epithelial cell lineage and, to a lesser extent, the derivatives of the interstitial cell lineage, are responsible for the reduced ability of foot regeneration.     

Alkaline phosphatase distribution in the plasma membrane of uterine epithelial cells is markedly altered during early pregnancy in the rat

Ultrastructural and light microscopic cytochemical methods were used to study the distribution and changes in distribution of alkaline phospatase in the apical plasma membrane of rat uterine epithelial cells during different stages of early pregnancy up to the time of attachment of the blastocyst. Reaction product generated by alkaline phosphatase (AP) was located along the apical plasma membrane at each stage investigated. However, a very different organization of reaction product was observed depending on the time during early pregnancy with a continuous pattern appearing all along the microvilli on day 1. This pattern was subsequently converted into a clumped and highly ‘patchy’ appearance around the time of blastocyst attachment by day 6 of pregnancy. This change in pattern and distribution was only seen on the luminal epithelial cells with glandular epithelial cells and blood vessels displaying an unchanging distribution.     

Characterization of intermediate filaments and their structural organization during epithelium formation in pigmented epithelial cells of the retina in vitro

Summary Retinal pigmented epithelial cells of chicken have circumferential microfilament bundles (CMBs) at the zonula adherens region. Isolated CMBs are polygons filled with a meshwork composed primarily of intermediate filaments; they show three major components of 200000, 55000, and 42000 daltons in SDS-gel electrophoresis. Here we have characterized the 55000-dalton protein immunochemically and ultrastructurally. Immunoblotting and immunofluorescence microscopy have shown that the 55000-dalton protein is an intermediate filament protein, vimentin.Vimentin filaments changed their distribution during differentiation of pigmented epithelial cells in culture. The protein in the elongated cells showed a fibroblast-type pattern of intermediate filaments. During epithelium formation, the filaments were uniformly distributed and formed a finer meshwork at the apical level. In pigmented epithelial cells that differentiated and matured in culture, vimentin and actin exhibited their characteristic behavior after treatment with colcemid. In the central to basal region of the cell, intermediate filaments formed thick perinuclear bundles. In the apical region, however, intermediate filaments changed in organization from a nonpolarized meshwork to a polarized bundle-like structure. Simultaneously, new actin bundles were formed, running parallel to the intermediate filaments. This suggests that there is some interaction between microfilaments and intermediate filaments in the apical region of these cells.     

Cell sorting during the regeneration of Hydra from reaggregated cells.

The role of cell sorting in the reorganization of Hydra cell reaggregates was studied. We quantitatively labeled ectodermal and endodermal cells by incubating whole animals in fluorescent beads or by injecting the beads into the gastric cavity. Beads were stably incorporated into the cells by phagocytosis. Our data show that dramatic cell sorting processes drive the formation of ectoderm and endoderm within the first 12 hr of reaggregation. After the ectoderm is established, no further rearrangement could be observed. We also tested the ability of cells to sort out with respect to their original position in Hydra by dissociating labeled apical and basal pieces of Hydra and measuring the clumping of labeled cells during reorganization. There was no increase in the clumping of cells during reorganization indicating that cell sorting is not involved in the formation of early activation centers. There was also no preferential incorporation of apically derived (presumptive head) tissue into tentacles that subsequently formed, indicating that after dissociation into single cells there is no predisposition of erstwhile presumptive head tissue to form heads.     

Functional differentiation and alveolar morphogenesis of primary mammary cultures on reconstituted basement membrane

An essential feature of mammary gland differentiation during pregnancy is the formation of alveoli composed of polarized epithelial cells, which, under the influence of lactogenic hormones, secrete vectorially and sequester milk proteins. Previous culture studies have described either organization of cells polarized towards lumina containing little or no demonstrable tissue-specific protein, or establishment of functional secretory cells exhibiting little or no glandular architecture. In this paper, we report that tissue-specific vectorial secretion coincides with the formation of functional alveoli-like structures by primary mammary epithelial cells cultured on a reconstituted basement membrane matrix (derived from Engelbreth-Holm-Swarm murine tumour). Morphogenesis of these unique three-dimensional structures was initiated by cell-directed remodelling of the exogenous matrix leading to reorganization of cells into matrix-ensheathed aggregates by 24 h after plating. The aggregates subsequently cavitated, so that by day 6 the cells were organized into hollow spheres in which apical cell surfaces faced lumina sealed by tight junctions and basal surfaces were surrounded by a distinct basal lamina. The profiles of proteins secreted into the apical (luminal) and basal (medium) compartments indicated that these alveoli-like structures were capable of an appreciable amount of vectorial secretion. Immunoprecipitation with a broad spectrum milk antiserum showed that more than 80% of caseins were secreted into the lumina, whereas iron-binding proteins (both lactoferrin and transferrin) were present in comparable amounts in each compartment. Thus, these mammary cells established protein targeting pathways directing milk-specific proteins to the luminal compartment. A time course monitoring secretory activity demonstrated that establishment of tissue-specific vectorial secretion and increased total and milk protein secretion coincided with functional alveolar-like multicellular architecture. This culture system is unique among models of epithelial cell polarity in that it demonstrates several aspects of epithelial cell polarization: vectorial secretion, apical junctions, a sequestered compartment and formation of a basal lamina. These lumina-containing structures therefore reproduce the dual role of mammary epithelia to secrete vectorially and to sequester milk proteins. Thus, in addition to maintaining tissue-specific cytodifferentiation and function, a basement membrane promotes the expression of tissue-like morphogenesis.     

Expression of carbohydrate antigens in the goat uterus during early pregnancy and on steroid-treated polarized uterine epithelial cells in vitro

Our objectives were to determine whether specific fucosylated carbohydrate antigens, associated with uterine receptivity in rodents, are expressed in pregnant caprine uterine tissues and polarized uterine luminal epithelial (ULE) cells in culture. Immunofluorescence microscopy on frozen endometrium revealed that expression of the H-type 1 antigen, confined to epithelial cells, was regulated during early pregnancy. Staining was high on Day 5 and low on Days 11 and 13. Strong, uniform apical staining was characteristic of ULE cells between Days 15 and 19 but declined markedly by Day 25. Immunofluorescence analysis of the apical surface of polarized ULE cells cultured in steroid-free medium revealed weak and diffuse staining for the H-type 1 antigen, while progesterone (P(4)) treatment resulted in the formation of aggregates of punctate staining along the apical surface. Domain-specific biotinylation of polarized ULE cells, coupled with streptavidin precipitation and Western blotting, revealed that six apical surface proteins (31, 33, 42, 55, 60, and 70 kDa) carry the H-type 1 antigen. Therefore, H-type 1 antigen expression is up-regulated in vivo during the periimplantation period, stimulated by P(4) on polarized ULE cells in culture, and may be a useful marker for uterine receptivity in this species.     

A head signal influences apical migration of interstitial cells in Hydra vulgaris

Although interstitial cells of hydra can migrate either apically or basally along the body column, there is a distinct bias toward apical cell accumulation. This apical bias could be produced by a local vectorial property of the tissue or it may be controlled by a more global property, such as a signal from the apical head region. The migration behavior of BrdU-labeled interstitial cells was examined in several types of grafts to distinguish between these two general types of migration control. Grafting BrdU-labeled midgastric region tissue into a host in either the normal or the reverse orientation had no effect on the apical bias, indicating that a local vectorial cue was probably not guiding cells apically. In grafts with heads or with feet at both ends of the body column, there was no directional bias in migration if the labeled tissue was equidistant from both ends. In the two-headed grafts, if the labeled tissue was closer to one end, there was a bias in the direction of the closer head. The results suggest that a graded signal emanating from the head creates the apical bias and may attract cells via chemotaxis. The apical bias is enhanced in decapitated animals regenerating a head, indicating that the attracting signal is present and is possibly stronger in regenerating heads. The signal for cell migration may be involved in a patterning process underlying head regeneration.     

Formation of pattern in regenerating tissue pieces of Hydra attenuata: I. Head-body proportion regulation

The precision with which an almost uniform sheet of hydra cells develops into a complete animal was measured quantitatively. Pieces of tissue of varying dimensions were cut from the body column of an adult hydra and allowed to regenerate. The regenerated animals were assayed for number of heads (hypostomes plus tentacle rings), head attempts (body tentacles), and basal discs. To ascertain whether the head and body were reformed in normal proportions, the average number of epithelial cells in the heads and bodies was measured. Pieces of tissue, from $\text{1}\text{2}$ to $\text{1}\text{20}$ an adult in size, formed heads that were a constant fraction of the regenerate. Thus, over a 10-fold size range, a proportioning mechanism was operating to divide the tissue into head area and body area quite precisely, but appeared to reach limits at the extremes of the range. However, the regenerates were not all normal miniatures with one hypostome and one basal disc. As the width-length ratio of the cut piece was increased beyond the circumference-length ratio of the intact body column, the incidence of extra hypostomes in the “head” and body tentacles and extra basal discs in the “body” rose dramatically. A proportioning mechanism based on the Gierer-Meinhardt model for pattern formation is presented to explain the results.     

Epithelial cell interaction in air-liquid interface culture

Summary A novel culture method has been developed to study the interaction of epithelial cells in the absence of a solid substratum. Starting with either a single cell suspension or aggregates, cells were floated at the interface of air and liquid culture medium. Two epithelial cell lines have been studied in this system: Madin-Darby canine kidney cells (MDCK), and a rat bladder tumor cell line (NBT-II). Starting with a single cell suspension of MDCK, the floating cells coalesced in 24 h into sheets of cells. The cells were morphologically polarized with the apical surface facing the liquid medium. Domes were observed regularly in these sheets of cells. NBT-II cells migrated actively from aggregates at the air-liquid interface. In this floating culture, NBT-II cells produced extensive cell processes similar to those seen in cells grown on a solid surface. Because cells at the air-liquid interface lack a solid substratum for adhesion, cell membrane processes such as lamellapodia, retraction fibers, pseudopods, and long, intercellular connections can only exert a tension equal to or less than the surface tension of the liquid. Dimethyl sulfoxide 2% stimulated desmosome formation in floating NBT-II cells, resulting in a cribriform pattern in the sheet of cells. This method of interface can lead to new understanding of morphogenesis of epithelial cells, and the mechanism, of cell motility and formation of cell processess. This research was supported by research grant CA14137 from the National Institutes of Health, Bethesda, MD, and in part by the W. W. Smith Charitable Trust, Rosemont, PA     

Motility of endodermal epithelial cells plays a major role in reorganizing the two epithelial layers in Hydra

Cell-cell interactions and cell rearrangements play important roles during development. Aggregates of Hydra cells reorganize into the two epithelial layers and subsequently form a normal animal. Examination of the formation of the two layers under various situations, indicates that the motility of endodermal epithelial cells, but not the differential adhesive forces of the two types of epithelial cells, plays the critical role in setting up the two epithelial layers. (1) When aggregates of ectodermal cells and of endodermal cells were placed in direct contact, the endodermal cells migrated into the interior of the ectodermal aggregate. This process was completely inhibited by cytochalasin B although initial firm attachment between the two aggregates was not blocked. (2) A single endodermal epithelial cell placed in contact with an ectodermal aggregate, actively extended pseudopod-like structures and migrated toward the center of the ectodermal aggregate. In contrast, an ectodermal epithelial cell remained in contact with an endodermal aggregate and never exhibited migratory behavior. Cytochalasin treatment of only endodermal epithelial cells abolished the migration. (3) One to 4 endodermal epithelial cells and/or ectodermal epithelial cells were placed in contact with one another forming up to 4-cell aggregates. Endodermal epithelial cells exhibited high motility that can be attributed to the migratory movement described above. Finally, formation of actin bundles, as visualized with rhodamine-phalloidin, was always correlated with pseudopod formation in endodermal epithelial cells during early and mid stages of aggregate formation.     

The Pseudomonas aeruginosa Type III Translocon Is Required for Biofilm Formation at the Epithelial Barrier

Clinical infections by Pseudomonas aeruginosa, a deadly Gram-negative, opportunistic pathogen of immunocompromised hosts, often involve the formation of antibiotic-resistant biofilms. Although biofilm formation has been extensively studied in vitro on glass or plastic surfaces, much less is known about biofilm formation at the epithelial barrier. We have previously shown that when added to the apical surface of polarized epithelial cells, P. aeruginosa rapidly forms cell-associated aggregates within 60 minutes of infection. By confocal microscopy we now show that cell-associated aggregates exhibit key characteristics of biofilms, including the presence of extracellular matrix and increased resistance to antibiotics compared to planktonic bacteria. Using isogenic mutants in the type III secretion system, we found that the translocon, but not the effectors themselves, were required for cell-associated aggregation on the surface of polarized epithelial cells and at early time points in a murine model of acute pneumonia. In contrast, the translocon was not required for aggregation on abiotic surfaces, suggesting a novel function for the type III secretion system during cell-associated aggregation. Supernatants from epithelial cells infected with wild-type bacteria or from cells treated with the pore-forming toxin streptolysin O could rescue aggregate formation in a type III secretion mutant, indicating that cell-associated aggregation requires one or more host cell factors. Our results suggest a previously unappreciated function for the type III translocon in the formation of P. aeruginosa biofilms at the epithelial barrier and demonstrate that biofilms may form at early time points of infection.     

Hym-301, a novel peptide, regulates the number of tentacles formed in hydra

Hym-301 is a peptide that was discovered as part of a project aimed at isolating novel peptides from hydra. We have isolated and characterized the gene Hym-301, which encodes this peptide. In an adult, the gene is expressed in the ectoderm of the tentacle zone and hypostome, but not in the tentacles. It is also expressed in the developing head during bud formation and head regeneration. Treatment of regenerating heads with the peptide resulted in an increase in the number of tentacles formed, while treatment with Hym-301 dsRNA resulted in a reduction of tentacles formed as the head developed during bud formation or head regeneration. The expression patterns plus these manipulations indicate the gene has a role in tentacle formation. Furthermore, treatment of epithelial animals indicates the gene directly affects the epithelial cells that form the tentacles. Raising the head activation gradient, a morphogenetic gradient that controls axial patterning in hydra, throughout the body column results in extending the range of Hym-301 expression down the body column. This indicates the range of expression of the gene appears to be controlled by this gradient. Thus, Hym-301 is involved in axial patterning in hydra, and specifically in the regulation of the number of tentacles formed.     

Trafficking of Crumbs3 during Cytokinesis Is Crucial for Lumen Formation

Although lumen generation has been extensively studied through so-called cyst-formation assays in Madin-Darby canine kidney (MDCK) cells, an underlying mechanism that leads to the initial appearance of a solitary lumen remains elusive. Lumen formation is thought to take place at early stages in aggregates containing only a few cells. Evolutionarily conserved polarity protein complexes, namely the Crumbs, Par, and Scribble complexes, establish apicobasal polarity in epithelial cells, and interference with their function impairs the regulated formation of solitary epithelial lumina. Here, we demonstrate that MDCK cells form solitary lumina during their first cell division. Before mitosis, Crumbs3a becomes internalized and concentrated in Rab11-positive recycling endosomes. These compartments become partitioned in both daughter cells and are delivered to the site of cytokinesis, thus forming the first apical membrane, which will eventually form a lumen. Endosome trafficking in this context appears to depend on the mitotic spindle apparatus and midzone microtubules. Furthermore, we show that this early lumen formation is regulated by the apical polarity complexes because Crumbs3 assists in the recruitment of aPKC to the forming apical membrane and interference with their function can lead to the formation of a no-lumen or multiple-lumen phenotype at the two-cell stage.     

Microfilaments, cell shape changes, and the formation of primary mesenchyme in sea urchin embryos.

Primary mesenchyme formation in sea urchin embryos occurs when a subset of epithelial cells of the blastula move from the epithelial layer into the blastocoel. The role of microfilaments in producing the cell shape changes that characterize this process, referred to as ingression, was investigated in this study. f-Actin was localized by confocal microscopy using labeled phalloidin. The distribution of f-actin was observed before, during, and after ingression and was correlated with cellular movements. Prior to the onset of ingression, staining became intense in the apical region of putative primary mesenchyme and disappeared following the completion of mesenchyme formation. The apical end of these cells constricted coincidentally with the appearance of the intensified staining, indicating that f-actin may be involved in this constriction. In addition, papaverine, a smooth muscle cell relaxant that interferes with microfilament-based contraction, and that was shown in this study to inhibit cytokinesis, diminished apical constriction and delayed ingression. Despite this interference with apical constriction, the basal surface of ingressing cells protruded into the blastocoel. It is suggested that apical constriction, while not necessary for ingression, does contribute to the efficient production of mesenchyme and that protrusion of the basal surface results from changes that occur independent of apical constriction.     

Stage-specific expression of the intermediate filament protein cytokeratin 13 in luminal epithelial cells of secretory phase human endometrium and peri-implantation stage rabbit endometrium

In preparation for blastocyst implantation, uterine luminal epithelial cells express new cell adhesion molecules on their apical plasma membrane. Since one mechanism epithelial cells employ to regulate membrane polarity is the establishment of specific membrane-cytoskeletal interactions, this study was undertaken to determine if new cytokeratin (CK) intermediate filament assemblies are expressed in endometrial epithelial cells during developmental stages related to blastocyst implantation. Type-specific CK antibodies were used for immunocytochemical and immunoblot analyses of 1) intermediate filament networks of the endometrial epithelium during embryo implantation in rabbits and 2) proliferative and secretory phases of the human menstrual cycle. CK18, a type I CK found in most simple epithelia, was expressed in all luminal and glandular epithelial cells of both the human and rabbit endometrium at all developmental stages analyzed; it was also strongly expressed in trophectoderm of the implanting rabbit blastocyst. In contrast, CK13, another type I cytokeratin, exhibited a regulated expression pattern in luminal, but not glandular, epithelial cells of secretory phase human and peri-implantation stage rabbit endometrium. Furthermore, in the rabbit implantation chambers, CK13 was predominantly localized at the cell apex of luminal epithelial cells, where it assembled into a dense filamentous network. These data suggest that the stage-specific expression of CK13 and a reorganization of the apical intermediate filament cytoskeleton of uterine luminal epithelial cells may play important functions in preparation for the implantation process.     

Microtubule integrity is essential for apical polarization and epithelial morphogenesis in the thyroid

In this study, we examined the contribution of microtubules to epithelial morphogenesis in primary thyroid cell cultures. Thyroid follicles consist of a single layer of polarized epithelial cells surrounding a closed compartment, the follicular lumen. Freshly isolated porcine thyroid cells aggregate and reorganize to form follicles when grown in primary cultures. Follicular reorganization is principally a morphogenetic process that entails the assembly of biochemically distinct apical and basolateral membrane domains, delimited by tight junctions. The establishment of cell surface polarity during folliculogenesis coincided with the polarized redistribution of microtubules, predominantly in the developing apical poles of cells. Disruption of microtubule integrity using either colchicine or nocodazole caused loss of defined apical membrane domains, tight junctions and follicular lumina. Apical membrane and tight junction markers became randomly distributed at the outer surfaces of aggregates. In contrast, the basolateral surface markers, E-cadherin and Na(+),K(+)-ATPase, remained correctly localized at sites of cell-cell contact and at the free surfaces of cell aggregates. These findings demonstrate that microtubules play a necessary role in thyroid epithelial morphogenesis. Specifically, microtubules are essential to preserve the correct localization of apical membrane components within enclosed cellular aggregates, a situation that is also likely to pertain where lumina must be formed from solid aggregates of epithelial precursors.